Liquid and ion transport by fetal airway and lung epithelia of mice deficient in sodium-potassium-2-chloride transporter.

Chloride (Cl(-)) movement across fetal lung epithelia is thought to be mediated by the sodium-potassium-2-Cl(-) cotransporter NKCC1. We studied the role of NKCC1 in Cl(-) and liquid secretion in late-gestation NKCC-null (-/-) and littermate control fetal mouse lung. NKCC -/- mice had decreased lung water compared with littermate controls (wet/dry: control, 8.01 +/- 0.09; NKCC -/-, 7.06 +/- 0.14). Liquid secretion by 17-d NKCC -/- distal lung explants was similar to control explants. Bumetanide inhibited basal liquid secretion in control but not NKCC -/- explants (expansion over 48 h: control, 35 +/- 4%; NKCC -/- 46 +/- 7%). Treatment with 4,4'-diisothiocyanto-stilbene-2,2'-disulfonic acid (DIDS) decreased liquid secretion in both control and NKCC -/- explants. Basal transepithelial potential difference (PD) of control tracheal explants was higher than that of NKCC -/- (control, -13.7 +/- 0.5 mV; NKCC -/-, -11.6 +/- 0.6 mV). Amiloride (10(-)(4) M) inhibited basal PD to the same extent in control and NKCC -/- mice. Terbutaline-stimulated hyperpolarization was less in NKCC -/- than in control tracheas (DeltaPD: control, -10.8 +/- 1.33 mV; NKCC -/-, -6.1 +/- 0.7 mV) and was inhibited by DIDS and acetazolamide in NKCC -/- but not wild-type explants. We conclude that NKCC is rate-limiting for transcellular Cl(-) transport, and that alternative anion transport mechanisms can sustain liquid production at near-normal levels in the fetal NKCC -/- mouse lung.

BRCA1 is a selective co-activator of 14-3-3 sigma gene transcription in mouse embryonic stem cells.

BRCA1 gene is a tumor suppressor for breast and ovarian cancers with the putative role in DNA repair and transcription. To characterize the role of BRCA1 in transcriptional regulation, we analyzed gene expression profiles of mouse embryonic stem cells deficient in BRCA1 using microarray technology. We found that loss of BRCA1 correlated with decreased expression of several groups of genes including stress response genes, cytoskeleton genes, and genes involved in protein synthesis and degradation. Previous study showed that BRCA1 is a transcriptional co-activator of p53 protein; however the majority of p53 target genes remained at the same expression levels in BRCA1 knockout cells as in the wild type cells. The only p53 target gene down-regulated with the loss of BRCA1 was 14-3-3 sigma, a major G(2)/M checkpoint control gene. Similar to cells with decreased 14-3-3 sigma activity, BRCA1-deficient cells were unable to sustain G(2)/M growth arrest after exposure to ionizing radiation. We find that BRCA1 induction of 14-3-3 sigma requires the presence of wild type p53 and can be regulated by a minimal p53 response element.

Intestinal ion transport in NKCC1-deficient mice.

The Na(+)-K(+)-2Cl(-) cotransporter (NKCC1) located on the basolateral membrane of intestinal epithelia has been postulated to be the major basolateral Cl(-) entry pathway. With targeted mutagenesis, mice deficient in the NKCC1 protein were generated. The basal short-circuit current did not differ between normal and NKCC1 -/- jejuna. In the -/- jejuna, the forskolin response (22 microA/cm(2); bumetanide insensitive) was significantly attenuated compared with the bumetanide-sensitive response (52 microA/cm(2)) in normal tissue. Ion-replacement studies demonstrated that the forskolin response in the NKCC1 -/- jejuna was HCO(3)(-) dependent, whereas in the normal jejuna it was independent of the HCO(3)(-) concentration in the buffer. NKCC1 -/- ceca exhibited a forskolin response that did not differ significantly from that of normal ceca, but unlike that of normal ceca, was bumetanide insensitive. Ion-substitution studies suggested that basolateral HCO(3)(-) as well as Cl(-) entry (via non-NKCC1) paths played a role in the NKCC1 -/- secretory response. In contrast to cystic fibrosis mice, which lack both basal and stimulated Cl(-) secretion and exhibit severe intestinal pathology, the absence of intestinal pathology in NKCC1 -/- mice likely reflects the ability of the intestine to secrete HCO(3)(-) and Cl(-) by basolateral entry mechanisms independent of NKCC1.

Dimerization of the calcium-sensing receptor occurs within the extracellular domain and is eliminated by Cys --> Ser mutations at Cys101 and Cys236.

Calcium-sensing receptors are present in membranes as dimers that can be reduced to monomers with sufhydryl reagents. All studies were carried out on the human calcium-sensing receptor tagged at the carboxyl terminus with green fluorescent protein (hCaR-GFP) to permit identification and localization of expressed proteins. Truncations containing either the extracellular agonist binding domain plus transmembrane helix 1 (ECD/TMH1-GFP) or the transmembrane domain plus the intracellular carboxyl terminus (TMD/carboxyl terminus-GFP) were used to identify the dimerization domain. ECD/TMH1-GFP was a dimer in the absence of reducing reagents, whereas TMD/carboxyl-terminal GFP was a monomer in the absence or presence of reducing agents, suggesting that dimerization occurs via the ECD. To identify the residue(s) involved in dimerization within the ECD, cysteine --> serine point mutations were made in residues that are conserved between hCaR and metabotropic glutamate receptors. Mutations at positions 60 and 131 were expressed at levels comparable to wild type in HEK 293 cells, had minimal effects on hCaR function, and did not eliminate dimerization, whereas mutations at positions 101 and 236 greatly decreased receptor expression and resulted in significant amounts of monomer in the absence of reducing agents. The double point mutant hCaR(C101S/C236S)-GFP was expressed more robustly than either C101S or C236S and covalent dimerization was eliminated. hCaR(C101S/C236S)-GFP had a decreased affinity for extracellular Ca2+ and slower response kinetics upon increases or decreases in agonist concentration. These results suggest that covalent, disulfide bond-mediated dimerization of the calcium-sensing receptor contributes to stabilization of the ECD and to acceleration of the transitions between inactive and active receptor conformations.